Effect Of Accelerated Aging Research Articles

Accelerated Aging Effects Observed In Vitro after an Exposure to Gamma-Rays Delivered at Very Low and Continuous Dose-Rate Equivalent to 1-5 Weeks in International Space Station.

Radiation impacting astronauts in their spacecraft come from a "bath" of high-energy rays (0.1-0.5 mGy per mission day) that reaches deep tissues like the heart and bones and a "stochastic rain" of low-energy particles from the shielding and impacting surface tissues like skin and lenses. However, these two components cannot be reproduced on Earth together. The MarsSimulator facility (Toulouse University, France) emits, thanks to a bag containing thorium salts, a continuous exposure of 120 mSv/y, corresponding to that prevailing in the International Space Station (ISS). By using immunofluorescence, we assessed DNA double-strand breaks (DSB) induced by 1-5 weeks exposure in ISS of human tissues evoked above, identified at risk for space exploration. All the tissues tested elicited DSBs that accumulated proportionally to the dose at a tissue-dependent rate (about 40 DSB/Gy for skin, 3 times more for lens). For the lens, bones, and radiosensitive skin cells tested, perinuclear localization of phosphorylated forms of ataxia telangiectasia mutated protein (pATM) was observed during the 1st to 3rd week of exposure. Since pATM crowns were shown to reflect accelerated aging, these findings suggest that a low dose rate of 120 mSv/y may accelerate the senescence process of the tested tissues. A mathematical model of pATM crown formation and disappearance has been proposed. Further investigations are needed to document these results in order to better evaluate the risks related to space exploration.

Accelerated degradation of PET-based photovoltaic backsheets under UV and acetic acid exposure

Despite initially certified in qualification tests, photovoltaic (PV) backsheets and entire systems often experience catastrophic failures within a few years of field deployment. Understanding the factors contributing to these failures is challenging due to the complex service conditions and composition of PV systems. In this study, we investigated the synergistic effects of UV exposure (an external weathering factor) and acetic acid (HAc, an internal weathering factor) on the degradation of PV backsheets. Polyethylene terephthalate (PET)-based backsheets, commonly used in PV systems, were selected as model samples. Key failure modes, including yellowing and cracking, were compared between PET backsheets aged with UV exposure alone and those exposed to both UV and HAc. The results revealed that the presence of HAc significantly accelerated the failure process of PET samples compared to those aged with UV and air alone. This additional acceleration was mainly attributed to the potential formation of hydroxyl radicals produced by HAc under UV exposure, which facilitates the chain scission reaction and the formation of chromophores. Density functional theory (DFT) calculations were also conducted to understand the accelerated aging effects induced by hydroxyl radicals. Additionally, combining UV/HAc exposure with mechanical stress resulted in even more accelerated degradation. These findings suggest that novel accelerated aging methods could be developed to better simulate field conditions, assess early failure risks, and enhance the design of robust and reliable PV products.

Metadata-conditioned generative models to synthesize anatomically-plausible 3D brain MRIs

Recent advances in generative models have paved the way for enhanced generation of natural and medical images, including synthetic brain MRIs. However, the mainstay of current AI research focuses on optimizing synthetic MRIs with respect to visual quality (such as signal-to-noise ratio) while lacking insights into their relevance to neuroscience. To generate high-quality T1-weighted MRIs relevant for neuroscience discovery, we present a two-stage Diffusion Probabilistic Model (called BrainSynth) to synthesize high-resolution MRIs conditionally-dependent on metadata (such as age and sex). We then propose a novel procedure to assess the quality of BrainSynth according to how well its synthetic MRIs capture macrostructural properties of brain regions and how accurately they encode the effects of age and sex. Results indicate that more than half of the brain regions in our synthetic MRIs are anatomically plausible, i.e., the effect size between real and synthetic MRIs is small relative to biological factors such as age and sex. Moreover, the anatomical plausibility varies across cortical regions according to their geometric complexity. As is, the MRIs generated by BrainSynth significantly improve the training of a predictive model to identify accelerated aging effects in an independent study. These results indicate that our model accurately capture the brain’s anatomical information and thus could enrich the data of underrepresented samples in a study. The code of BrainSynth will be released as part of the MONAI project at https://github.com/Project-MONAI/GenerativeModels.

Assessment of Accelerated Aging Effect of Bio-Oil Fractions Utilizing Ultrahigh-Resolution Mass Spectrometry and k-Means Clustering of van Krevelen Compositional Space.

Bio-oils contain a substantial number of highly oxygenated hydrocarbons, which often exhibit low thermal stability during storage, handling, and refining. The primary objectives of this study are to characterize the hydroxyl group in bio-oil fractions and to investigate the relationship between the type of hydroxyl group and accelerated aging behavior. A bio-oil was fractionated into five solubility-based fractions, classified in two main groups: water-soluble and water-insoluble fractions. These fractions were then subjected to chemoselective reactions to tag molecules containing hydroxyl groups and analyzed by negative-ion electrospray ionization 21 T Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS). The fractions were also subjected to accelerated aging experiments and characterized by FT-ICR MS and bulk viscosity measurements. Extracting insightful information from ultrahigh-resolution data to aid in predicting upgrading methodologies and instability behaviors of bio-oils is challenging due to the complexity of the data. To address this, an unsupervised learning technique, k-means clustering analysis, was used to semiquantify molecular compositions with a close Euclidean distance within the (O/C, H/C) chemical space. The combination of k-means analysis with findings from chemoselective reactions allowed the distinctive hydroxyl functionalities across the samples to be inferred. Our results indicate that the hexane-soluble fraction contained numerous molecules containing primary and secondary alcohols, while the water-soluble fraction displayed diverse groups of oxygenated compounds, clustered near to carbohydrate-like and pyrolytic humin-like materials. Despite its high oxygen content, the water-soluble fraction showed minimal changes in viscosity during aging. In contrast, a significant increase in viscosity was observed in the water-insoluble materials, specifically, the low- and high-molecular-weight lignin fractions (LMWL and HMWL, respectively). Among these two fractions, the HMWL exhibited the highest increase in viscosity after only 4 h of accelerated aging. Our results indicate that this aging behavior is attributed to an increased number of molecular compositions containing phenolic groups. Thus, the chemical compositions within the HMWL are the major contributors to the viscosity changes in the bio-oil under accelerated aging conditions. This highlights the crucial role of oxygen functionality in bio-oil aging, suggesting that a high oxygen content alone does not necessarily correlate with an increase of viscosity. Unlike other bio-oil categorization methods based on constrained molecule locations within the van Krevelen compositional space, k-means clustering can identify patterns within ultrahigh-resolution data inherent to the unique chemical fingerprint of each sample.

Visco-plastic deformation characteristics of accelerated-aging asphalt mixture containing reclaimed asphalt pavement regenerated with crumb rubber based on Hamburg Wheel-Track test

The regeneration of the reclaimed asphalt pavement (RAP) with incorporation of crumb rubber was a cleaner alternative for reducing the fossil and ore resources consumption. For the desert area like Egypt, the rut of reclaimed pavement was principal contradiction during a long service. This work mainly characterized the visco-plastic deformation of accelerated-aging rubberized reclaimed asphalt mixture based on Hamburg Wheel-Track test. Four mixtures were designed by two contents of RAP (15% and 30%), two contents of crumb rubber (5% and 15%), and two asphalts (pen-#70 and pen-#90). Specifically, this work focused on the determination of accelerated aging effect, and analysis of rutting deformation fitting including overall deformation and visco-plastic deformation. Then, effect of accelerated aging time and material compositions on visco-plastic deformation was analyzed. In addition, the correlation analysis among indicators evaluating rutting deformation of mixture was conducted, and the correlation analysis between rutting deformation of mixture and average recovery rate at 3.2 kPa of extracted bitumen was completed. The results demonstrated that the accelerated aging equivalent factor of sunlight was approximately 6, meaning that one day of accelerated aging was equivalent to six days of natural aging in Cairo. With the accelerated aging time increased, resistance to rutting deformation of rubberized reclaimed asphalt mixture was promoted with the incorporation of RAP, crumb rubber and soft matrix binder. Meanwhile, dynamic stability, derived from fitting curve of visco-plastic deformation, was positively correlated with accelerated aging time, and it could accurately evaluate visco-plastic deformation characteristics of reclaimed mixture. Finally, visco-plastic deformation characteristics of reclaimed mixture was closely related to the permanent deformation resistance of binder at high temperature.

Dietary diversity score and the acceleration of biological aging: a population-based study of 88,039 participants

ObjectivesOur study aimed to investigate the association of dietary diversity score (DDS), as reflected by five dietary categories, with biological age acceleration. DesignA cross-sectional study. Setting and participantsThis study included 88,039 individuals from the UK Biobank. MethodsBiological age (BA) was assessed using Klemerae-Doubal (KDM) and PhenoAge methods. The difference between BA and chronological age represents the age acceleration (AgeAccel), termed as “KDMAccel” and “PhenoAgeAccel”. AgeAccel > 0 indicates faster aging. Generalized linear regression models were performed to assess the associations of DDS with AgeAccel. Similar analyses were performed for the five dietary categories. ResultsAfter adjusting for multiple variables, DDS was inversely associated with KDMAccel (βHigh vs Low = −0.403, 95%CI: −0.492 to −0.314, P < 0.001) and PhenoAgeAccel (βHigh vs Low = −0.545, 95%CI: −0.641 to −0.450, P < 0.001). Each 1-point increment in the DDS was associated with a 4.4% lower risk of KDMAccel and a 5.6% lower risk of PhenoAgeAccel. The restricted cubic spline plots demonstrated a non-linear dose-response association between DDS and the risk of AgeAccel. The consumption of grains (βKDMAccel = −0.252, βPhenoAgeAccel = −0.197), vegetables (βKDMAccel = −0.044, βPhenoAgeAccel = −0.077) and fruits (βKDMAccel = −0.179, βPhenoAgeAccel = −0.219) was inversely associated with the two AgeAccel, while meat and protein alternatives (βKDMAccel = 0.091, βPhenoAgeAccel = 0.054) had a positive association (All P < 0.001). Stratified analysis revealed stronger accelerated aging effects in males, smokers, and drinkers. A strengthening trend in the association between DDS and AgeAccel as TDI quartiles increased was noted. ConclusionsThis study suggested that food consumption plays a role in aging process, and adherence to a higher diversity dietary is associated with the slowing down of the aging process.

Experimental and numerical analysis of the fracture behavior of an epoxy-based marine coating under static tension and accelerated aging effect in NaCl solution

Experimental and numerical analysis of the fracture behavior of an epoxy-based marine coating under static tension and accelerated aging effect in NaCl solution

Diffusion imaging markers of accelerated aging of the lower cingulum in subjective cognitive decline.

Alzheimer's Disease (AD) typically starts in the medial temporal lobe, then develops into a neurodegenerative cascade which spreads to other brain regions. People with subjective cognitive decline (SCD) are more likely to develop dementia, especially in the presence of amyloid pathology. Thus, we were interested in the white matter microstructure of the medial temporal lobe in SCD, specifically the lower cingulum bundle that leads into the hippocampus. Diffusion tensor imaging (DTI) has been shown to differentiate SCD participants who will progress to mild cognitive impairment from those who will not. However, the biology underlying these DTI metrics is unclear, and results in the medial temporal lobe have been inconsistent. To better characterize the microstructure of this region, we applied DTI to cognitively normal participants in the Cam-CAN database over the age of 55 with cognitive testing and diffusion MRI available (N = 325, 127 SCD). Diffusion MRI was processed to generate regional and voxel-wise diffusion tensor values in bilateral lower cingulum white matter, while T1-weighted MRI was processed to generate regional volume and cortical thickness in the medial temporal lobe white matter, entorhinal cortex, temporal pole, and hippocampus. SCD participants had thinner cortex in bilateral entorhinal cortex and right temporal pole. No between-group differences were noted for any of the microstructural metrics of the lower cingulum. However, correlations with delayed story recall were significant for all diffusion microstructure metrics in the right lower cingulum in SCD, but not in controls, with a significant interaction effect. Additionally, the SCD group showed an accelerated aging effect in bilateral lower cingulum with MD, AxD, and RD. The diffusion profiles observed in both interaction effects are suggestive of a mixed neuroinflammatory and neurodegenerative pathology. Left entorhinal cortical thinning correlated with decreased FA and increased RD, suggestive of demyelination. However, right entorhinal cortical thinning also correlated with increased AxD, suggestive of a mixed pathology. This may reflect combined pathologies implicated in early AD. DTI was more sensitive than cortical thickness to the associations between SCD, memory, and age. The combined effects of mixed pathology may increase the sensitivity of DTI metrics to variations with age and cognition.

Discoloration and Surface Changes in Spruce Wood after Accelerated Aging.

Spruce wood is widely used in outdoor applications, but its susceptibility to degradation under exposure to sunlight and moisture is a major concern. This study investigates the impact of accelerated aging on spruce wood's surface chemistry, microstructure, geometry, and discoloration. The study was performed in two outdoor aging modes: dry and wet. The accelerated aging effects were evident in the changes in spruce wood structure, as well as in the other studied properties. During aging, it developed significant discoloration. Under simulated rainless outdoor conditions (dry mode), spruce wood gradually became dark brown. Under conditions involving rain (wet mode), the discoloration was qualitatively different from the dry mode. FTIR spectroscopy showed that during the accelerated aging of wood, lignin was mainly degraded, especially in the early stages of the process. A linear correlation was found between the changes in lignin and the color changes in the wood. There was an increase in carbonyl groups in the dry mode, which contributed to the color change and was also influenced by changes in extractives. The wet mode caused the leaching out of carbonyl groups. The observed decrease in cellulose crystallinity, together with the degradation of hydrophobic lignin, may result in the increased hydrophilicity of photodegraded wood. For both modes, there were different changes in the wood micro- and macrostructure, reflected in the surface morphology. The roughness increased during the aging process in both modes. The slightest changes in the roughness parameters were identified in the grain direction in the dry mode; the most evident was that the roughness parameters increased perpendicular to the grain in the wet mode. The demonstrated mechanism backing up the aging-related changes to the spruce wood structure and the relations unveiled between these changes and the changes in the spruce wood surface properties can provide an issue point for seeking ways how to mitigate the negative effects of the environmental factors the wood is exposed to.

Senescence: A DNA damage response and its role in aging and Neurodegenerative Diseases.

Senescence is a complicated, multi-factorial, irreversible cell cycle halt that has a tumor-suppressing effect in addition to being a significant factor in aging and neurological diseases. Damaged DNA, neuroinflammation, oxidative stress and disrupted proteostasis are a few of the factors that cause senescence. Senescence is triggered by DNA damage which initiates DNA damage response. The DNA damage response, which includes the formation of DNA damage foci containing activated H2AX, which is a key factor in cellular senescence, is provoked by a double strand DNA break. Oxidative stress impairs cognition, inhibits neurogenesis, and has an accelerated aging effect. Senescent cells generate pro-inflammatory mediators known as senescence-associated secretory phenotype (SASP). These pro-inflammatory cytokines and chemokines have an impact on neuroinflammation, neuronal death, and cell proliferation. While it is tempting to think of neurodegenerative diseases as manifestations of accelerated aging and senescence, this review will present information on brain ageing and neurodegeneration as a result of senescence and DNA damage response.

The impact of subjective cognitive decline on aging effects in the brain as measured by diffusion tensor imaging

AbstractBackgroundDiffusion tensor imaging (DTI) can separate subjective cognitive decline (SCD) participants who progress to mild cognitive impairment and those who do not 1. We explored the effect age and memory performance has on DTI measures in SCD and controls in the hippocampal cingulum bundle, which is typically affected early in the course of Alzheimer’s disease2.Method325 participants Cam‐CAN 3 (127 SCD) older than 55 were included in the analysis. Diffusion imaging data was collected on a 3T Siemens TIM Trio scanner with a 32‐channel head coil for 0, 1000 and 2000 s/mm2 b‐values and 30 gradient directions. Preprocessing and calculation of the DTI metrics fractional anisotropy (FA, mean diffusivity (MD), radial diffusivity (RD) and axial diffusivity (AxD) were completed using MRTrix3, FSL and MATLAB. The hippocampal cingulum bundle regions of interest (ROIs) were extracted from the ICBM‐DTI‐81 atlas. Memory was assessed using the delayed story recall (DSR) task from WMS‐III. Linear regression models were completed in R. Gender was included as a nuisance variable.ResultThere were no differences in gender or age distribution between cohorts, however participants with SCD had a 14% lower DSR score (Table 1). There was a significant interaction effect between age and cohort in MD, AxD, and RD (Figure 1), as well as between memory and age in AxD (Figure 2). In post‐hoc analyses, compared to controls, the SCD group showed a stronger correlation with age in MD, AxD, and RD (Figure 1) while participants with worse memory showed a stronger correlation with age in MD (Figure 2), indicating an accelerated aging effect.ConclusionParticipants with SCD and worse memory present with an accelerated aging effect, showing steeper variations in diffusion microstructure with age. Since SCD is likely to be a preclinical stage of Alzheimer’s disease, future work will analyze this effect with more advanced diffusion microstructure models to further elucidate the underlying pathophysiology. • Selnes P, Aarsland D, Bjornerud A, et al. J Alzheimers Dis. 2013;33(3):723‐36. • Jack Jr CR, Knopman DS, Jagust WJ, et al. The Lancet Neurology. 2013;12(2):207‐16. • Shafto MA, Tyler LK, Dixon M, et al. BMC neurology. 2014;14(1):1‐25.

The impact of subjective cognitive decline on aging effects in the brain as measured by diffusion tensor imaging

AbstractBackgroundDiffusion tensor imaging (DTI) can separate subjective cognitive decline (SCD) participants who progress to mild cognitive impairment and those who do not 1. We explored the effect age and memory performance has on DTI measures in SCD and controls in the hippocampal cingulum bundle, which is typically affected early in the course of Alzheimer’s disease2.Method325 participants Cam‐CAN 3 (127 SCD) older than 55 were included in the analysis. Diffusion imaging data was collected on a 3T Siemens TIM Trio scanner with a 32‐channel head coil for 0, 1000 and 2000 s/mm2 b‐values and 30 gradient directions. Preprocessing and calculation of the DTI metrics fractional anisotropy (FA, mean diffusivity (MD), radial diffusivity (RD) and axial diffusivity (AxD) were completed using MRTrix3, FSL and MATLAB. The hippocampal cingulum bundle regions of interest (ROIs) were extracted from the ICBM‐DTI‐81 atlas. Memory was assessed using the delayed story recall (DSR) task from WMS‐III. Linear regression models were completed in R. Gender was included as a nuisance variable.ResultThere were no differences in gender or age distribution between cohorts, however participants with SCD had a 14% lower DSR score (Table 1). There was a significant interaction effect between age and cohort in MD, AxD, and RD (Figure 1), as well as between memory and age in AxD (Figure 2). In post‐hoc analyses, compared to controls, the SCD group showed a stronger correlation with age in MD, AxD, and RD (Figure 1) while participants with worse memory showed a stronger correlation with age in MD (Figure 2), indicating an accelerated aging effect.ConclusionParticipants with SCD and worse memory present with an accelerated aging effect, showing steeper variations in diffusion microstructure with age. Since SCD is likely to be a preclinical stage of Alzheimer’s disease, future work will analyze this effect with more advanced diffusion microstructure models to further elucidate the underlying pathophysiology.1. Selnes P, Aarsland D, Bjornerud A, et al. J Alzheimers Dis. 2013;33(3):723‐36.2. Jack Jr CR, Knopman DS, Jagust WJ, et al. The Lancet Neurology. 2013;12(2):207‐16.3. Shafto MA, Tyler LK, Dixon M, et al. BMC neurology. 2014;14(1):1‐25.

Mechanical Properties of Light-Transmitting Concrete and Its Durability Performance under the Effects of Accelerated Aging

Abstract Although concrete has been used extensively as a structural material for buildings since ancient times, light-transmitting concrete (LTC), also referred to as translucent concrete, is an innovative and attractive building material for the construction industry to enhance aesthetic and energy-saving properties. This research paper aims to investigate the mechanical properties of LTC with different optical fiber arrangements with three optical fiber ratios, respectively, 1, 1.6, and 2.4 %. The durability performance of LTC under the effects of accelerated aging is also investigated. Polymethyl methacrylate (PMMA) optical fibers with two arrangements were used in the concrete specimens. One of the LTC groups that had a linear optical fiber arrangement was labeled as ARlin. The other LTC group with bundle optical fiber arrangements was labeled as ARbun. The prepared concrete consisted of cement, fine aggregate, water, mineral additive, acrylic polymer, and superplasticizer. The flexural strengths of LTC with PMMA optical fibers placed longitudinally or laterally were determined. The compressive strengths of LTC specimens with different arrangements were compared. Accelerated aging effects under wetting-drying, freezing-thawing, and high temperature were applied to the ARlin group to investigate these effects on the mechanical properties of LTC. The results of the experiments indicate that the optical fiber arrangements affect the flexural strength, compressive strength, and light transmittance of LTC. The light transmittance increases with the optical fiber content. It is also seen that the flexural strengths and light transmittance of LTC specimens decrease significantly after the high-temperature effect. According to the test results, it is also concluded that LTC with 0.5-mm-diameter optical fibers in a linear arrangement can be used as a construction material under external conditions.

AAV1.NT-3 gene therapy in the SOD1KO mouse model of accelerated sarcopenia.

Sarcopenia, an age-related loss of muscle mass, is a critical factor that affects the health of the older adults. The SOD1KO mouse is deficient of Cu/Zn superoxide dismutase, used as an accelerated aging model. We previously showed that NT-3 improves muscle fibre size by activating the mTOR pathway, suggesting a potential for attenuating age-related muscle loss. This study assessed the therapeutic efficacy of AAV1.NT-3 in this accelerated aging model. Twelve 6months old SOD1KO mice were injected intramuscularly with a 1×1011 vg dose of AAV1.tMCK.NT-3, and 13 age-matched SOD1KO mice were used as controls. The treatment effect was evaluated using treadmill, rotarod and gait analyses as well as histological studies assessing changes in muscle fibre, and fibre type switch, in tibialis anterior, gastrocnemius, and triceps muscles, and myelin thickness by calculating G ratio in sciatic and tibial nerves. Molecular studies involved qPCR experiments to analyse the expression levels of mitochondrial and glycolysis markers and western blot experiments to assess the activity of mTORC1 pathway. Treatment resulted in a 36% (154.9 vs. 114.1; P<0.0001) and 76% increase (154.3 vs. 87.6; P<0.0001) in meters ran, with treadmill test at 3 and 6months post gene delivery. In addition, the treated cohort stayed on rotarod 30% (52.7s vs. 40.4s; P=0.0095) and 54% (50.4s vs. 32.7s; P=0.0007) longer, compared with untreated counterparts at 3 and 6months post injection. Gait analysis, performed at endpoint, showed that stride width was normalized to wild type levels (29.3mm) by an 11% decrease, compared with untreated cohort (28.6mm vs. 32.1mm; P=0.0014). Compared with wild-type, SOD1KO mice showed 9.4% and 11.4% fibre size decrease in tibialis anterior and gastrocnemius muscles, respectively, which were normalized to wild type levels with treatment. Fibre diameter increase was observed prominently in FTG fibre type. G ratio analysis revealed hypomyelination in the tibial (0.721) and sciatic (0.676) nerves of SOD1KO model, which was reversed in the NT-3 cohort (0.646 and 0.634, respectively). Fibre size increase correlated with the increase in the p-S6 and p-4E-BP1 levels, and in the glycolysis markers in tibialis anterior. Alterations observed in the mitochondrial markers were not rescued with treatment. Overall, response to NT-3 was subdued in gastrocnemius muscle. This study shows that AAV1.NT-3 gene therapy protected SOD1KO mouse from accelerated aging effects functionally and histologically. We further confirmed that NT-3 has potential to activate the mTOR and glycolytic pathways in muscle.

Restoration of physical properties on an aged crumb rubber modified bitumen adding a bio-based recycling agent

Reclaimed asphalt pavement (RAP) is a popular practice in the pavement industry due to environmental and economic benefits. But, RAP must be processed and treated before being reused in new pavements for preventing premature failures. A widely adopted strategy consists of adding recycling agents, and specifically rejuvenators, to mitigate the aging of the RAP binder. From the circular economy perspective, also crumb rubber (CR) from end-of-life tyres have been used to prepare binders with enhanced properties. The actual possibility of using the RAP derived from removed and/or reprocessed pavements containing CR particles (CR-RAP) for the formulation of new suitable mixtures is still a little-explored topic. Moreover, the available rejuvenators tailored on RAP have not yet evidence of effectiveness in producing asphalt mixtures containing CR-RAP. For this purpose, unaged, aged and rejuvenated blends with and without CR were studied through a rheological characterisation to evaluate the potential restoration of their physical properties when a bio-based recycling agent is added. The results of viscosity, frequency sweep, creep-recovery and multiple stress creep recovery (MSCR) tests have highlighted on the one hand the significant contribution of CR in reducing the accelerated aging effects of the binder, on the hand the effectiveness of the rejuvenator in restoring, more clearly at low temperatures, the rheological behaviour of the binders (above all for CRMB) similar to the unaged condition.

Modification of surface characteristics of ophthalmic biomaterial-polymethyl methacrylate induced by cobalt 60 gamma irradiation.

This study aims to observe the accelerated aging effect of 60Co gamma (γ) irradiation on poly (methyl methacrylate) (PMMA) under extreme conditions and determine the influence of different media states on aging. PMMA samples were prepared at room temperature under varying media conditions, including air and deionized water immersion. Then, the samples were irradiated with different doses (50, 250, 500, and 1000 KGy) of 60Co γ-rays. The compositional changes of the PMMA samples exposed to the rays at different periods were determined via Fourier transform infrared spectroscopy. The light transmission of the samples was characterized through ultraviolet-visible spectrophotometry, and the surface wettability of the samples was assessed via water contact angle measurements. Surface and microscopic changes in material morphology were analyzed using optical microscopy, ImageJ software, and scanning electron microscopy. Relative molecular mass and glass transition temperature were analyzed via gel permeation chromatography and differential scanning calorimetry. Thus, a comprehensive analysis of the effect of 60Co γ irradiation on the aging properties of PMMA was performed.

Accelerated Aging Effects on Color Change, Translucency Parameter, and Surface Hardness of Resin Composites.

Background The aging process can induce a change in the surface microstructure of materials, the chemical compositions of matrices, and the filler particles of resin composites. This study is aimed at evaluating the effects of accelerated artificial aging (AAA) on the color change, translucency parameter (TP), and surface hardness of resin composites. Methods Five resin composite materials (Tetric N-Ceram, Filtek Z250, Charisma Smart, Herculite Classic, and Escom100) were evaluated. A spectrophotometer was used for color measurements (L∗, a∗, and b∗). TP and color changes (ΔE00) were calculated using the CIEDE2000 formula. The resin materials were subjected to aging for 300 hours. The hardness and TP values were measured before and after AAA. One- and two-way ANOVA and the Tukey test were used. The significance level was accepted as p < 0.05. Results Escom100 had significantly higher ΔE00 values than the other resin composites, and Charisma Smart had significantly lower ΔE00 values than the other tested materials (p < 0.05). Before and after AAA, Charisma Smart had the lowest TP values, and Filtek Z250 exhibited the highest hardness values (p < 0.05). For TP and surface hardness, the effect size value of the composite material was found to be higher than that of AAA. Conclusions After AAA, the investigated resin composites had ΔE00 values that were above clinically acceptable thresholds. After aging, the tested materials generally exhibited decreases in L∗ values and a∗ values, while increases in b∗ values were observed. The ΔTP values of the resin composites were similar. AAA significantly increased the surface hardness of the tested materials.

Accelerated Aging Effect in Physical and Thermo-mechanical Properties of Maize Starch Biocomposites Reinforced with Agave Salmiana Fibers from Different Leaf Ages

Accelerated Aging Effect in Physical and Thermo-mechanical Properties of Maize Starch Biocomposites Reinforced with Agave Salmiana Fibers from Different Leaf Ages

Effect of fiber type and content on the performance of extruded wood fiber cement products

This study presents the physical, mechanical, and durability characteristics of the extruded cement fiber products manufactured with various types of wood fibers. Four types of wood fiber cement products, one each produced with softwood, hardwood, recycled wood, and a blend of hard/softwood fibers were investigated in the experimental program. For each type of fiber mixtures, the effect of fiber content (fiber to cement ratio) was investigated at 5%, 10%, and 15% levels. These products were tested in unaged and aged conditions after exposure to accelerated aging effects. Test results showed decrease in bulk specific gravity and increase in water absorption capacity of the wood fiber cement composites with increase in fiber content. Considerable increase in flexural toughness was recorded with increase in fiber content for the softwood fiber products. After exposure to accelerated aging conditions comprising of freeze-thaw cycles, wet-dry cycles, saturation, and warm water exposure, the softwood fibers-based cement composite provided the highest level of flexural strength and stiffness. Furthermore, fiber cement composites having 10% fiber content retained a target flexural strength of 8–10 MPa besides showing good flexural stiffness after aging. Test results of this study help in identifying wood fiber reinforcement conditions which yield extruded fiber cement products with the balance of physical, mechanical, and durability characteristics suiting different building applications.

Experimental study on hygrothermal accelerated aging effects of transparent fire resistive wood structure coatings

In this paper, the durability of fire performance of a transparent fire resistive coating for wood structure was studied using hygrothermal accelerated aging. The aging effects was analysed using SEM/EDS and fire test. The results show that after 21 days of aging, the flame-retardant components gradually precipitate to the surface. The coating basically loses its expansion ability and the char layer shows a low-strength lamellar structure. The flame-retardant time of the coating decreased by 43.48% from 23 min to 13 min.